Method and System for Electronically Securing an Electronic Device Using Physically Unclonable Functions

ABSTRACT

The invention is directed to a system for securing an integrated circuit chip used in an electronic device by utilizing a circuit or other entity to produce physically unclonable functions (PUF) to generate a security word, such as an RSA public or private key. A PUF, according to its name and configuration, performs functions that are substantially difficult to be duplicated or cloned. This allows the invention to provide a unique and extremely secure system for authentication. In operation, the stored parameters can be used to more efficiently and quickly authenticate the device without the need to run the burdensome security key generation processes without compromising the level of security in the device. Such a system can be used to substantially eliminate the time to produce security keys when a user needs to authenticate the device at power up or other access point.

RELATED APPLICATION

This application claims the benefit of U.S. Provisional Patent Application No. 60/928,864, filed on May 11, 2007, entitled Method and System for Electronically Securing an Electronic Device Using Physically Uclonable Functions

BACKGROUND

The invention relates generally to technology for electronically securing electronic devices using security keys and, more particularly, to systems, devices and methods for securing devices using physically unclonable functions (PUFs) to generate security keys. As described herein, PUFs are known in the art as circuits, components, processes or other entities capable of generating an output, such as a digital word or a function that is resistant to cloning. For example, a device that has such a PUF embodied therein would be difficult to clone in a manner to generate the same PUF output with another device.

Security in electronic devices has become a major concern of manufacturers and users of such devices. This is particularly true for devices such as computers, personal hand held devices, cellular phones and other devices that contain sensitive information. Developers of electronic devices continuously strive to develop systems and methods that make their products impervious to unauthorized access or use.

At the same time, most all applications have cost limitations that must betaken into account. For example, if a complicated authentication process requiring storage and computing resources were employed on an integrated circuit, the costs incurred may not justify the cost of security accomplished, particularly if the end product were a low cost and mass produced consumer product.

Additionally, the time expended in processing is a concern in many applications. For example, if a fingerprint sensor were employed on a laptop computer, it would need to process computations quickly. Consumers are very particular about convenience of use in any product. So, if a user needs to wait a long period of time for the computer to authenticate the sensor, the product may not be accepted. Moreover, if the user access is a barrier to a time critical operation, such as in a manufacturing process, delayed access resulting from an authentication process could be disastrous. These and other factors are taken into account when designing devices that use such operations.

Many techniques are known for securing electronic devices and applications. Traditionally, in cryptology, RSA (a fanciful acronym derived from the initials of the three developers of the algorithm Ron Rivest, Adi Shamir and Len Adleman of Massachusetts Institute of Technology (MIT)) is an algorithm that is used for public key encryption, and is believed to be secure given sufficiently long keys. Generally, public keys are widely used to encrypt messages and are employed in authentication routines. The decryption or authentication requires a private key. Thus, encryption techniques are not secret, but decryption can be done only by the holder of the private key. This algorithm as well as other algorithms and techniques are well known to those skilled in the art, and are widely employed in security and authentication applications. Generally, the following steps can be performed to generate public and private keys:

1. Choose two large prime numbers p and q such that p≠q, randomly and independently of each other.

2. Compute n=pq.

3. Compute the quotient φ(n)=(p−1)(q−1).

4. For the public exponent e choose an integer e>1 that is coprime to φ(n).

I.e., gcd(e,φ(n))=1.

5. Compute the private exponent d such that the congruence relation de≡1 (mod φ(n)) is satisfied.

The prime numbers can be probabilistically tested for primality. A popular choice for the public exponents is e=2¹⁶+1=65537. Some applications choose smaller values such as e=3,5, or 35 instead. This is done in order to make implementations on small devices (e.g., smart cards) easier, i.e. encryption and signature verification are faster. However, choosing small public exponents may lead to greater security risks. Steps 4 and 5 can be performed with the extended Euclidean algorithm; see modular arithmetic. Step 3 may alternatively be implemented as λ(n)=lcm(p−1,q−−1) instead of φ(n)=(p−1)(q−1).

The public key consists of

n, the modulus, and

e, the public exponent (sometimes encryption exponent).

The private key consists of

n, the modulus, which is public and appears in the public key, and

d, the private exponent (sometimes decryption exponent), which must be kept secret.

For reasons of efficiency sometimes a different form of the private key (including CRT parameters) is stored:

p and q, the primes from the key generation,

d mod (p−1) and d mod (q−1) (often known as dmp1 and dmq1)

(1/q) mod p (often known as iqmp)

Though this form allows faster decryption and signing using the Chinese Remainder Theorem (CRT), it considerably lowers the security. In this form, all of the parts of the private key must be kept secret. Yet, it is a bad idea to use it, since it enables side channel attacks in particular if implemented on smart cards, which would most benefit from the efficiency win. If a smart card process, for example, starts with y=x^(e)modn and let the card decrypt that. Thus, it computes y^(d)(mod p) or y^(d)(mod q) whose results give some value z. Now, if an error is induced in one of the computations, then gcd(z−x,n) will reveal p or q.)

In operation, if a sending party transmits the public key to a receiving party, and the sending party keeps the private key secret, then p and q are sensitive, since they are the factors of n, and allow computation of d given e. If p and q are not stored in the CRT form of the private key, they are securely deleted along with the other intermediate values from the key generation.

This process of generating security keys is a complex and computation heavy process, particularly in routine authentication processes. Also, producing an integrated circuit with advanced security features is expensive using conventional systems and methods. In particular, generating prime numbers is taxing on a system design, requiring processor resources, additional chip space for storage and related circuitry, as well as other resources needed for authentication. Utilizing security keys outside an integrated circuit chip, off-chip, is also expensive, requiring additional circuitry and integrated circuit chips. Moreover, performing such processes off-chip is less secure, leaving the authentication process vulnerable to attack.

Also, in practice, conventional authentication processes take time to perform, and often leave a user waiting for the process to complete. For example, in authenticating a typical software application, a user must wait while such a process is completed before access or use is allowed. In many applications, particulary with small electronic devices such as laptop computer, personal data assistants (PDAs), cellular phones, and other devices, this can be burdensome for the device processor as well as for an impatient user. Using the processors and other hardware available in today's small common electronic devices, computing the public and private RSA key pair can take anywhere from 10 to 30 seconds. Even on fast personal computers, times of 1 to 3 seconds are common. Such time delays are undesirable in modern devices.

One approach could be to employ a PUF to more securely provide a security word for use in generating security keys. This would eliminate the need for storage of a public or private key on a device. Conventional approaches have addressed such a configuration in prior art publications. One example, U.S. Pat. No. 6,161,213 discloses the use of PUFs for component chip identification and other related applications. For example, a PUF could be used to produce a unique word for use in an RSA public/private key generation algorithm so that the component chip always produced the same public/private key pair. There are many problems with this approach. First, consistent production of a number by a circuit is not guaranteed. It is known that uniqueness of a number generated from a PUF circuit in a component chip is possible, but it cannot be produced consistently. In practice, the unique number generated, a digital number, changes upon the excitation of the PUF circuit, and different numbers are produced. As discussed above, using conventional methods, authentication using such means requires significant resources and takes such time and resource consuming processes are not desired in most applications, and are a great impediment to adoption.

However, conventional technology is not adequate for utilizing such identification. Using conventional methods, the PUF output would be used as a starting point, followed by the application of a complex and very time consuming algorithm to produce the public and private key pairs. Moreover, each time the keys are needed for authentication, the algorithm would need to be repeated, again needing to repeat the same complex and resource consuming algorithm to produce the public and private keys. Also, for security reasons, it is not desired to store the key pairs in non-volatile memory. Indeed, the purpose of having a PUF is to eliminate the storage of unique numbers that can be read easily by an intruder trying to bypass or otherwise food the authentication process. Thus, in a consumer application, if a fingerprint sensor for example, if the delays had to occur upon each authentication, consumer product manufacturers would be reluctant to adopt such a system. Consumers would simply not tolerate such delays. Faster and more convenient systems would be much more easily adopted and accepted.

Thus, there exists a great need in the art for a more efficient means to accurately and efficiently produce RSA keys for component chip and related devices, particularly to avoid the conventional complex and time consuming process used in prior art systems and processes for generating security keys each time a device needs to be authenticated. The need must address the tradeoffs such as the level of security provided, the related cost of manufacture and the resulting speed of operation. As will be seen, the invention provides a means to overcome the shortcomings of conventional systems in an elegant manner.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A is an illustration of a device configured with a security system according to the invention;

FIG. 1B is an illustration of a set up system for a device configured with a security system according to the invention;

FIG. 2A is a flow chart illustrating a setup and authentication method according to the invention;

FIG. 2B is a flow chart illustrating a set-up method according to the invention;

FIG. 2C is a flow chart illustrating an authentication method according to the invention;

FIG. 3 is a diagrammatic view of a sample PUF circuit employed with the invention;

FIG. 4A is a diagrammatic view of a device configured according to the invention illustrating the operating mode of such a device after it is manufactured; and

FIG. 4B is a diagrammatic view of a device configured according to the invention illustrating the set-up mode of such a device either in manufacturing or upon first use of the device.

DETAILED DESCRIPTION

The invention is directed to a system for securing an integrated circuit chip used in an electronic device by utilizing a circuit or other entity to produce physically unclonable functions (PUF) to generate a security word, such as an RSA public or private key. A PUF, according to its name and configuration, performs functions that are substantially difficult to be duplicated or cloned. This allows the invention to provide a unique and extremely secure system for authentication.

As described herein, different embodiments and configurations are possible in devices, systems and methods embodying the invention. The embodiments described here, are only intended as examples, and are not intended as limitations on the spirit and scope of the invention. This includes any type of means to accomplish certain functions that pertain to the invention. Furthermore, to the extent that any means plus function language is used in the claims, they are not limited to embodiments described herein, but contemplate and include any and all types components, devices, systems and method steps known or are to be developed in the future by those skilled in the art. And, those skilled in the art will understand that different configurations are possible without departing from the spirit and scope of the invention, which is defined by the appended claims, future claims submitted during prosecution in this and related applications, and equivalents of such claims.

The security word is used to develop a transfer function and related data that can be used to generate RSA keys and other security keys and related data used to authenticate the device, without the need to run the burdensome security key generation processes and without compromising the level of security in the device. Such processes may be run in a setup mode and only once when the device is manufactured or upon initial power up.

In a setup mode, the PUF circuit can produce a unique ID for the chip, which can be used to obscure the storage of critical security information as well as the transfer function parameters required to access the information. Once the device is setup, the transfer function can then be processed using the critical security information when authenticating the device in an operational mode. Unlike conventional devices, the setup procedure needs to be performed only once, whether it is in production or upon initial power up of the device, in order to establish the parameters needed to be stored in the device. In operation, the stored parameters can be used to more efficiently and quickly authenticate the device without the need to run the burdensome security key generation processes without compromising the level of security in the device. Such a system can be used to substantially eliminate the time to produce security keys when a user needs to authenticate the device at power up or other access point. In operation, the device can quickly and securely produce security keys, such as RSA keys and signature keys, and to perform the related algorithms. The invention allows for non-volatile storage of transfer function parameters that will allow a system to mathematically utilize the PUF output to get the desired output.

The invention, very generally, is directed to a system and method for providing individualized security for a device without the need to individually program the device. Since the IC chip has the ability to generate a unique identifier using the PUF circuit, each device would have a unique security process to authenticate the device. Furthermore, since the unique identifier is different for each device, it provides both a unique and secure means to authenticate the device.

This can have broad reaching applications for many different devices. For example, an MP3 digital music device, such as the Apple™ IPOD™ for example, could have an IC enabled according to the invention, where a unique ID is required to authenticate the device before downloading digital music files. According to the invention, if a service were established with the device that required authentication before downloading music files, such a device could be enabled to authenticate itself with a unique ID generated with the use of a PUF circuit before the service would download anything. The invention provides a unique, secure and consistent means to provide such a product and related service. This has been a great concern for music providers, as well as producers of devices that comply with digital rights. This area of interest is known as digital rights management (DRM), where the rights of content owners of music, video and other content are of great concern. There are some conflicting interests, namely the interests of consumers who purchased such content and who wish to freely use and share such content. This is in some contrast to the owners of the rights to such content who have a significant interest in controlling the distribution of such content. According to the invention, an MP3 or equivalent device can be configured for downloading and consuming music, video or other content in a secure manner using a unique authentication process. Many other potential applications are possible, and the invention has wide reaching and useful prospects for new and improved devices having unique and secure authorization cap abilities. And, those skilled in the art will understand that the invention is substantially broad in its application, and many such applications can be developed given this disclosure and skills known in the art.

In operation, a transfer function that utilizes a PUF output or its derivative can be stored on a chip, and is used along with a PUF output to generate security keys for use in authentication. The transfer function can be stored during manufacture, or may be generated and stored upon initial power up or initiation by a user in the field, such as a consumer setting up a device or an original equipment manufacturer (OEM) employing a component into a larger product. In fact, a device or component configured according to the invention can be configured One example of an OEM application is as a fingerprint sensor having a PUF configured according the invention being installed and incorporated with a laptop computer, for example. A substantial improvement over conventional approaches, the invention provides a means to generate security keys that do not leave the chip. This is a vast improvement over conventional systems and methods, where the security of a device is substantially improved by better securing an authentication process on a chip, obviating operations formerly done off the chip. And, this is true in the manufacture of a device, such as a PUF circuit configured according to the invention in an IC chip, and also in operation. Thus, a device can be configured with a novel and secure authentication process without sensitive security information leaving the device or configured IC chip during manufacture or during operation.

Utilizing the invention, an IC chip can be configured to perform operations to authenticate a device without causing the RSA keys to be transferred externally to a location outside the IC chip. All authentication operations, less perhaps the initial external excitation, may occur entirely on the chip. The keys can be generated, processed or otherwise utilized entirely on the chip without need to be transferred or otherwise communicated to a physical location outside the internal IC circuitry. The keys need only be transmitted, transferred, processed or otherwise communicated to components and entities within the IC within which the security keys are generated.

After the transfer function is generated and stored, upon subsequent power up operations or other authentication events, the security words and the corresponding transfer function and related data can be used in a more efficient manner to authenticate the device. This is accomplished without any compromise in security or cost. In fact, compared to conventional systems and methods in the prior art, security may even be enhanced, and cost reduced. These benefits are realized by virtue of a PUF to uniquely differentiate each device, and to enable the production of security keys such as public and private security keys and device signatures in a reproducible manner. As will be seen, the invention accomplishes this in an elegant manner, and provides a novel and useful means to uniquely identify a device for authentication purposes.

The embodiments discussed below and illustrated in the drawings are but examples of various embodiments of the invention. In each of these examples, preferred embodiments are discussed and illustrated, where different components and combinations of components are shown and discussed in a cooperative manner in order to explain the features, operations and benefits the invention can provide as embodied therein. Such examples, however, are not intended to be all-inclusive, and other embodiments are possible. Those skilled in the art will understand that other embodiments are possible, and are in fact likely, as different applications require individual trade-offs given their design parameters. Also, different features, functions, operations or components may be incorporated together on a single device, such as an integrated circuit chip having components embedded thereon, or a printed circuit board having various components connected together. Device variations of some functions may exist on-chip, off-chip, or on entirely separate components or indeed separate devices. Such design decisions and related trade-off determinations will necessarily take into account the level of security desired, cost analysis, operation or setup timing and other factors.

Different combinations and permutations of components, features and configurations, whether located in or outside a device, on or off an integrated circuit chip, may be devised according to the invention. Depending on the parameters of a particular application, different combinations may result without departing from the spirit and scope of the invention, which are defined by the appended claims and their equivalents, as well as any claims presented in co-pending applications and their equivalents.

Referring to FIG. 1A, very generally, the device 102 is configured with a security application that enables authentication according to the invention. This application involves and includes both hardware and software components for combined use in authentication of the device. A transfer function circuit 103 is configured to perform operations that define the transfer function of the device. A PUF circuit 114 is configured to produce a security word upon excitation, where the word produced embodies a unique identification of the circuit that produces the PUF output by mere virtue of its manufacture. This PUF output is then processed along with a transfer function values to produce security keys, such as public and private RSA keys, product signature keys, or other types of security keys for use in an authentication process. The transfer function may be an algorithm, perhaps as simple as addition of values, where the transfer function combines offset values generated by authentication operations, examples of which are discussed herein. These values may be pre-computed, concurrently computed or subsequently offset values, either within the same circuit, or computed remotely. A processor 104 may be configured with arithmetic logic 106 or other components for processing transfer function parameters, which are stored in nonvolatile memory 108, including security parameters and other criteria parameters discussed below.

At its origin, the PUF is manufactured under standard design rules to conform with the design of the device within which it is incorporated. Upon a first initiation, the device is configured in a setup mode, where resource consuming computations are performed. In this setup mode, offset values are generated that, when combined with the PUF output, can be used to generate security keys whenever authentication is desired. This can have wide reaching application wherever and whenever authentication is desired, whether it be for proximal or remote access authorization to data, applications, security systems, or other secured entities; for use authorization of devices, hardware, software or other entities; authentication of authorized devices for use alone or in combination with other devices, such as with a fingerprint sensor that needs to be authenticated before it can be used as an access device for a secured electronic device such as a laptop computer; or for any other process where authorization is desired.

Examples of devices that could be manufactured or otherwise accessorized with devices or entities configured according to the invention include personal desktop and lap top computers, cellular telephones, content recording devices such as MP3 players or the equivalent, batter packs, ink cartridges, devices involving DRM and content downloads, smart cards, access identification cards, and other devices where stored data needs to be protected. Such devices may perform financial transactions, internet related transactions, and other transactions where, again, stored or otherwise processed data is desired to be protected. In conventional prior art devices, such computations would be required upon each instance of authentication. In such prior art devices, resources are strained and much time is required to perform such authentications. In modern devices, power and computational resources are very restricted, and an authentication processes can greatly affect the ability for a device to be manufactured and operate within such restrictions. If a device is not able to be manufactured or operate within such restrictions, it may not be accepted or adopted in particular products. However, if a device could operate within such restrictions, it could be widely adopted, becoming ubiquitous in one or many product areas.

For example, electronic memory storage may be embedded on an integrated circuit to reduce operation time and increase security. In another application, memory may exist on a separate integrated circuit, off-chip, to save costs by storing security parameters, offsets or related data along with other information. According to the invention, in many applications, such tradeoffs will be substantially obviated given the unique and powerful features provided. Nonetheless, those skilled in the art will understand that, given this specification, different embodiments can be developed using conventional knowledge and skills without departing from the spirit and scope of the invention as defined by the appended claims and their equivalents. Thus, those skilled in the art will understand that the determination of which exact implementation or embodiments are preferred will depend on the given application.

In a setup mode, the PUF circuit can produce a unique ID for the chip, which can be used to obscure the storage of critical security information as well as the transfer function parameters required to access the information. Once the device is setup, the transfer function can then be processed using the critical security information when authenticating the device. Unlike conventional devices, the setup procedure needs to be performed only once, whether it is in production or upon initial power up of the device, in order to establish the parameters needed to be stored in the device. In operation, the stored parameters can be used to more efficiently and quickly authenticate the device without the need to run the burdensome security key generation processes without compromising the level of security in the device. Such a system can be used to substantially eliminate the time to produce security keys when a user needs to authenticate the device at power up or other access point. In operation, the device can quickly and securely produce security keys, such as RSA keys and signature keys, and to perform the related algorithms. The invention allows for non-volatile storage of transfer function parameters that will allow a system to mathematically utilize the PUF output to get the desired output.

The invention is directed to a system for securing an integrated circuit chip used in an electronic device by utilizing a circuit or other entity to produce physically unclonable functions (PUF) for use in generating security word, such as an RSA public or private key. There are many applications for such a circuit, including authenticating a software application associated with the chip, giving access to secure information from the device having the chip (and accordingly excluding unapproved devices from access to the information), and many other applications

As an example of a device that can greatly benefit if configured according to the invention, a fingerprint sensor with a small embedded processor could utilize a PUF to enable a remote computer to verify the identity of the sensor to assure that no one had replaced the sensor with another. The remote computer could further assure that the original sensor had not been compromised, and still further could verify that a transmitted fingerprint was sent by that sensor. This could assure that no one had injected a false fingerprint into the communications channel used by the sensor and the remote computer. This provides a highly secure identity verification method that would be useful in many applications, including for example online banking transactions to verify that a funds transfer was being initiated by the owner of the funds. In another example, the invention could be incorporated in security applications to authenticate a sensor and the corresponding communications link before granting access to a fingerprint-secured area. Such a sensor can be used in many applications, such as laptop computers, smart cards, cellular phones, etc.

In one embodiment, in a device that has no programmable storage, the invention can provide a device, system and method to store the transfer function at a remote location. Such a remote location may be separate memory, such as random access memory (RAM), a separate cache storage, or other type of memory. Utilizing other features of the invention, such as PUF circuitry, authentication can be achieved with significant security.

The invention can extend to many other applications where security in authentication is desired. In the fingerprint sensor example, employing the invention in the sensor with the small embedded processor would greatly reinforce the security of the sensor. This is done by configuring a secret key and a public key using a unique and consistent output from the PUF circuit. Where the sensor is incorporated in another system, the invention can help better secure such a system by requiring compatibility with a particular sensor product. This is done by obscuring a product signature using the PUF and related security information stored on the device. The signature would be the same for all products manufactured together by a company, and would verify that the product incorporated in the system was indeed manufactured by a certain company. This would add security for a system by preventing unauthorized access to devices.

The invention utilizes a PUF in a new and unique way from conventional applications. The PUF circuit can produce a unique ID for the chip, which can be used to obscure the storage of critical security information and to greatly reduce the time required to produce security keys, such as RSA keys. The invention allows for permanent non-volatile storage of a transfer function that will allow a system to mathematically utilize the PUF output to produce the desired security keys. In the case of generating RSA key pairs, the PUF can be used to produce a unique output, and the keys can then be generated. A transfer function can then be encoded in nonvolatile memory that would enable for rapid mathematical reproduction of the public and private keys, given the PUF output. This allows reproduction of the keys without the lengthy process of key generation. Moreover, it enables this without any compromise to security. Even though the transfer function parameters are stored in nonvolatile memory, the output of the PUF circuit is still unknown. And, therefore, the security keys cannot be deciphered without the PUF output. Thus, security keys cannot be generated without the actual PUF output. As a result, another device that does not have the actual PUF circuit would not be able to generate the keys and cannot artificially generate the keys without the actual PUF circuit. Given the possible variations in a PUF circuit, it is virtually impossible to reproduce the PUF output, and thus it would be equally as impossible to reproduce the security keys.

In one embodiment, the invention provides for a system and method for generating security keys for use in electronically authenticating or locking and unlocking a device, software application, or other secured entity, where a security word can be generated by a PUF circuit, and separate transfer function parameters can be stored in nonvolatile memory. Together, these can be used to authenticate a device in a novel and useful manner, with an increased level of security compared to conventional systems and methods. The security word produced by a PUF is physically unique to the IC in the device, and does not need to be stored in memory, and thus can not be easily misappropriated. It must be derived by interrogating the device to provoke an output signal that is indicative of the physical circuit components. The transfer function parameters can be stored in nonvolatile memory, and can be retrieved in nonvolatile memory and combined with the security word from the PUF to authenticate the device for a user. Since the transfer function parameters would be useless for authenticating the device without the security word, and since it is derived by different means, greatly improved security is provided for authenticating a device.

In operation, physically unclonable information is read from a device. According to the invention, the device has installed on it a PUF circuit or the like onto an integrated circuit (IC). The PUF circuit is configured to generate an identification number that identifies the IC in which it is installed. Generally, the PUF circuit may be made up of a plurality of identification cells formed within the IC, where each cell has an output that is a substantial function of random parametric variations in the IC and thus unique to the IC by virtue of its manufacture. A measuring device may monitor the output of the identification cells to generate an ID that is unique to the device, where the ID is also a substantial function of random parametric variations in the identification cells. It is known to those skilled in the art that there are enough manufacturing process variations across ICs produced in the same process to uniquely characterize ICs. It has also been proven that reliable authentication can be performed using words derived from such unique characterizations. The invention exploits such knowledge, and utilizes this to provide a novel and useful method of authenticating a device or application using PUF circuits.

Once the ID is received by the measuring device, it can then compute an output security parameter from the PUF, such as a unique number that is indicative of the ID. This may be done in a number of ways, such as a stimulation circuit configured to send stimulation signals to the PUF circuit in order to provoke a unique output signal. For example, a signal can be transmitted to the PUF, which would in turn generate a response signal that is unique to the PUF according to its unique physical characteristic parameters that are created upon the manufacture of the IC on which the PUF resides. More details on this process are discussed below. In addition to the unique ID, according to the invention, a transfer function can be identified or otherwise derived. This transfer function can be used along with the ID to authenticate the device by way of the IC. This transfer function can be stored in nonvolatile memory for subsequent use.

Thus, in operation, the unique ID and transfer function can be determined when the IC is manufactured, and can be associated with a device, such as a laptop, smart card, cell phone, or other device. Upon power up of the device by a user, the device can be interrogated for the unique ID, which can then be used as a security word for identifying the device. The resulting security word can be used along with the transfer function to interrogate the device in order to identify and verify the device to give a user access. Thus, the invention provides a system and method for providing a security key and transfer function for authenticating a device, where the security key is physically unique to the IC in the device, and does not need to be stored in memory. The security key must be derived by interrogating the device to provoke an output signal that is indicative of the physical circuit components, such as PUF components that are created upon manufacture of the IC that is incorporated in the device. The transfer function can be stored in nonvolatile memory. Thus, the transfer function can be retrieved in nonvolatile memory, and combined with the security word to authenticate the device for a user. The security word is not stored in memory, and thus not susceptible to misappropriation. The transfer function, even if it were misappropriated, would be useless for authenticating the device without the security word, which is derived by completely different means, and not simply retrieved from storage.

Referring to again to FIG. 1A, a diagrammatic view of one embodiment 100 of the invention is illustrated. There are two general aspects of the system and method of the invention. One aspect is implemented and performed during production of an IC used in a device, and another is the product of manufacture embodied in the device that is used in authenticating the device during normal operations of the device. The former, illustrated as device 102 in FIG. 1B, may only need to be performed once, and may be part of a manufacturing process for the IC, or could also be performed upon initial power up of a device or other authentication process of the device. The latter, illustrated as device 102 in FIG. 1A, is employed each time a user powers up or otherwise initiates the device after the security key and transfer function have been established, and authentication is performed to identify the device and authorized operation by a user. The authentication may include identifying a subject device from a remote device, which would interrogate the subject device by sending a signal that excites or otherwise enables the subject device to identify itself. The signal sent by the remote device may include encrypted data sent via a communication channel sent in order to provoke a response by the subject device, such as a response signal embodying a public key and a product signature for example, discussed in more detail below. The device may be a laptop computer, a personal data assistant (PDA), a cellular telephone, or any other device for which authentication is desired prior or operation for security, authentication of a system or process to be used by the device whether located on the device or remotely, or for other purposes.

For example, manufactures that sell security devices or components for use in combination with other components, such as the fingerprint sensor discussed above that is sold for use with other devices to secure access, have an interest in authenticating the component devices. This prevents counterfeit devices that may be used to penetrate the security of a device. Also, manufacturers that sell software may want to authenticate the device on which the software is used to ensure that the software is not copied for unauthorized use on other devices. Often, manufacturers produce and sell software programs and applications to users for individual use, and others are sold as enterprise packages for use by multiple authorized users within an organization Such software manufacturers have a strong interest in ensuring that such programs are not copied onto unauthorized devices, such as laptops. The invention provides a means for manufacturers of such software to authenticate users by particular devices, preventing unauthorized copying or use. Secured devices configured according to the invention have features that allow for their highly secured authentication adding to the integrity of the security devices or components by making them more secure from counterfeits or unauthorized breaches or attacks.

The device 102 includes processor 104 configured to perform operations by executing software and performing operations in arithmetic logic 106. The processor may be a dedicated microprocessor implemented on an integrated circuit, a general-purpose computer, or may be simple logic circuitry configured to perform necessary operations for authentication of the device, and may include other operations related to general or specific operations of the device. According to the invention, the operations required for authentication have been greatly simplified for normal device operations where authentication is performed. Thus, less sophisticated processing circuitry and related software are required to perform such processes. Setup procedures perform the resource intensive security algorithms that, prior to the invention, were required each time a device was authenticated. According to the invention, these operations only need to be performed once upon setup. The setup procedure may be performed once upon the manufacture of the device or up on initial powering up of the device.

Thus, for example, a user may purchase a device such as a laptop or desktop computer for personal use and, upon first powering up the device, the device may perform the authentication computations in a setup mode. This may take considerable time at first, but, according to the invention, the user would only need to be inconvenienced once. The setup operations produce security parameters that are stored in memory. After setup operations are complete, more streamlined operations utilizing the stored parameters are used for routine authentication procedures. As discussed in more detail below, these parameters generated at setup are used during normal authentication operations, and by much of the same circuitry, to generate security keys such as RSA public and private keys as well as product signatures. These security keys can be used to authenticate the device for various purposes.

Alternatively, the intensive setup procedures may be performed periodically, either according to a time or use table or upon predetermined events. This may occur when a device is reintroduced in a market, or if there is a change in security codes or operations as determined by a manufacturer or mass user of a device to maintain the security and integrity of such devices produced by the manufacturer. Those skilled in the art will understand that, depending on the application, different security and maintenance procedures could be developed and maintained according to the invention by a manufacturer in order to produce products with optimum security.

Still referring to FIG. 1A, execution of software causes operations to occur in response to signals generated by the processor. Software is stored in nonvolatile memory 108, including security parameters 110 which, along with a word generated from the PUF circuit 114, provide a security key for authentication. The nonvolatile memory 108 further includes authentication interface 111 for enabling the device to be authenticated by an outside entity, or to otherwise be authenticated for use. The interface may be software code that, when executed by a processor of some type, is configured to enable communication between the subject device and a remote authenticating device. Alternatively, the interface may include hardware or a combination of hardware and software. Other critical parameters 112 may be stored in nonvolatile memory 108, including parameters that disable the PUF output from being presented on the IC external interface; parameters that disable the critical parameters in the nonvolatile memory from being presented on the IC external interface; and parameters that subsequently disable the critical parameters from being stored or overwritten from the IC external interface. The system may further include random access memory (RAM) 116 and/or read-only memory (ROM) 118 memory for processor and/or device operations.

In operation, an outside source or proximal interrogation source 120 may interrogate the device 102 for security and/or authentication. Interrogation source 120 includes a processor 122 for performing operations by executing software stored in memory 124. Software man include authentication unit 125 configured to cause the processor 122 to perform methods and processes for authenticating device 102. Interrogation unit 126 is configured to enable the processor to interrogate the PUF circuit 114 in order to provoke the PUF circuit to generate a security word in response. Device application 128 is configured to cause the processor to perform validity operations authentication operations, such as validity operations for example, in order to determine whether the security word from the PUF circuit is authentic. Using the security word and the security parameters 110 retrieved from memory 108, the application 128 can determine whether to authenticate the operation of the device 102. This is discussed in more detail below.

Referring to FIG. 1B, a system 101 is illustrated for setting up the device, including determining a transfer function, so that the device can be efficiently authenticated each time it is powered up by a user or otherwise initiated. The components of the device utilized in this process includes the PUF circuit 114, which is a substantially permanent entity configured to generate a consistent security word for identifying the device. A setup circuit 105 may be a separate entity all of its own, or may include the PUF circuit. In a preferred embodiment, the setup circuit 105 and the transfer function circuit 103 (FIG. 1A) coincide in the device, and some components are shared between the processes. Nonvolatile memory 108 includes transfer function storage 109 for storing the transfer function generated or otherwise derived by setup system 137. By virtue of its creation during the manufacture of the device, the PUF circuit is unique to the device within the design and manufacturing processes used to produce the PUF circuit. Since the manufacturing process operations within certain parameters, and since each device is produced separately, each PUF circuit is unique within certain tolerances according to the circuit parameters. Therefore, the individual security word produced by each PUF circuit is unique, or indeed randomly determined by the manufacturing process. However, the security word for each PUF circuit, once established, is consistently reproducible for authentication purposes. The word generated by the PUF circuit is unique to each PUF circuit produced by the manufacturing process.

The setup system 137 includes a processor 138 that is configured to perform setup operations by executing software stored in memory 140. PUF interrogator unit 142 is configured, when executed by the processor 138, to stimulate or otherwise interrogate the PUF circuit via communication link 139 to network or bus connection 130, and also via device link 131. In return, the PUF sends a security word for use in the setup process performed by the setup system 137. In practice, this may be performed multiple times to ensure an accurate reading of the security word to ensure a fair reading and testing for authentication. The PUF word analyzer circuit 144 is configured to analyze the PUF word to ensure that the output is that of a consistent word that can be duplicated for authentication purposes. The RSA key generator unit 146 is configured to generate a reliable security word for the PUF that can be consistently reproduced in subsequent initializations by a user for authentication. Transfer function generator 148 is configured to derive or otherwise generate a transfer function that can be used in conjunction with the security word generated by the PUF circuit to authenticate the device 102.

Once set up, the device may be interrogated by a remote device for authentication and would produce one or more security keys, such as RSA public or private keys, a product signature, or other types of security keys. In practice, it may be practical to run the authentication process in order to test whether the setup process properly set up the device. Then, subsequent authentication processes could be performed using the improved system within the device, without the need to perform the burdensome authentication processes. This is because these processes, though still critical, are performed during setup and not during routine authentication processes.

Referring to FIG. 2A, one embodiment of a method configured according to the invention is illustrated. The process is divided up into two parts, the setup process 200(a) and the operations process 200(b). In step 202, a security word is read from a PUF circuit. This may be done by internally or peripherally stimulating the PUF circuit to produce a security word in response. In step 204, an RSA key is generated by using the security word. In step 206, a security parameter is generated, which is part of the authentication process according to the invention. In step 208, a transfer function is identified or otherwise derived, this is discussed further below. In step 210, the transfer function is stored in nonvolatile memory. This process may be performed upon initial power up or initialization of the device, or in production before the device is ever used or sold. Either way, the cumbersome process of establishing a security key and deriving a transfer function using the PUF circuit is only required once. Afterwards, the device can be authenticated by simply using the security word generated from the PUF and the transfer function stored in memory.

The rest of the process 200(b) illustrated in FIG. 2A is indicative of the reduced process then required to authenticate the device. In step 212, the device is powered up or otherwise initialized. In step 214, a security key is generated by the PUF. This may be accomplished by an interrogating entity stimulating or otherwise interrogating the PUF circuit form a proximal or external device. In step 216, the transfer function is retrieved from nonvolatile memory. In step 218, the authentication process is initiated. This may include adding, subtracting or otherwise processing the PUF security key and the transfer function to compute an RSA key. This RSA key may be compared against a master key value in order to determine whether the device is authentic. It is then determined whether the device is valid. If not, an error signal may be generated in step 224. If the device is valid, then the device is authenticated in step 226.

Referring to FIGS. 2B and 2C, a more detailed flow chart of the setup mode process is illustrated in FIG. 2B, and a more detailed flow chart of the operational mode process is illustrated in FIG. 2C. These functions of each the setup mode and the operational mode are described further below in the context of the hardware circuitry and software in the particular embodiments of FIGS. 4A and 4C. However, the process described here is in no way limited to the particular embodiments described herein, but extend to any setup or operational circuitry or software the embodies the functions described herein.

Referring first to FIG. 2B, the process 228 is first performed to produce a PUF output, specifically a verified PUF output for use in setting up the device according to the invention. In step 230, a command for setup is received. In step 232, a PUF output is generated, which is an electronic signal that embodies a unique security word that is unique to a PUF, whether it is a PUF integrated circuit or other entity. For the setup process, it is desired to increase the integrity of the security key generation process so that substantially consistent parity bits and transfer function parameters (such as transfer function offset values) are generated. Accordingly, more consistent security keys would result. For this, a consistent PUF output is preferred.

In the next step, step 234, a verification process is performed to produce a refined PUF output. It has been discovered that a PUF output can be reliably repeated using statistically based techniques. In general, a PUF output can be repeatedly sampled, and simple statistical processing can be employed to arrive at a consistent number. This process can be done both in the setup process and operation process to substantially ensure that the most accurate PUF output is read for use in setting up and establishing the parity bits and the transfer function parameters, such as the offset values discussed herein. For example, a PUF output can be generated 3 or more times, and the outputs can be compared to find consistent values. If a PUF word is 448 bits for example, a subset of each word can be used to compare to other words to determine consistent outputs. In practice, certain bits can toggle back and forth from one PUF output to the next generated output. Given proper statistical analysis, substantially secure authentication can be accomplished.

When reading a PUF output, most bits can be stable and consistently produce the same output word. A few bits, however, may change or toggle from one read to another. In verifying the PUF output, a process can be invoked that ensures a more consistent PUF output. For example, the PUF output can be read a number of times, such as 5 times for example, and a statistical algorithm can be performed to determine which PUF output is to be used in subsequent processes. This improves subsequent error correction processes, and improves the overall authentication process and sub-processes described herein. The verified output is then generated in step 236. Alternatively, the verification process may occur after the error correction. Those skilled in the art will understand that different configurations are possible without departing from the spirit and scope of the invention, which is defined by the appended claims and their equivalents.

From here, the verified PUF output is used to generate the different security keys and parity values, specifically in this example embodiment of the invention, offset-P in process 237(a), offsets in process 238(b), parity bits in process 237(c), and offset-S in process 237(d). Each of these outputs is used to generate values needed to produce security keys, including but not limited to the RSA public and private keys and signature keys described herein. These values are derived during the setup process, and offset values and parity bits are stored in nonvolatile memory for use in generating security keys during the operational mode of the device. According to the invention, the burdensome algorithms for producing security keys are performed during the setup process so that they do not need to be performed each time the device is authenticated. When the offset values and parity bits are established in the nonvolatile memory, security keys can be produced using the PUF output together with these values in simple operations that do not required extensive processing by a data processor. This makes the process fast, less burdensome on device resources, and, given the novel manner in which the security keys are produced, the unique process does not compromise security of the device.

First, to produce offset-P in process 237(a), a pseudo random number generation process is performed in step 238 for use in generating the offset-P, which is used to produce a private key. Those skilled in the art will understand that different types of pseudo random number generation processes exist and can be used in a device configured according to the invention. In this process, a seed-P is generated in step 240, which is a numerical value generated from the pseudo random number generator. Using this seed value, a prime number generation process is performed in step 241 with a prime number generator. A prime number is generated in step 242. Those skilled in the art will understand that different types of prime number generation processes exist and can be used in a device configured according to the invention. Typically, a number is chosen, and it is tested whether it is prime. If not another number is chosen, sometimes by adding a value to the number, and testing it again in an iterative process. Once a number is found that is prime, it is used. In step 244, the prime number generated in step 242 is combined with the seed-P value to produce an offset-P. This may be done with a simple addition or subtraction logic circuit, a multiplier circuit, or other arithmetic unit. The offset-P is generated in step 245, and stored in step 246, such as in nonvolatile memory, on-chip memory, or other memory storage.

Next, to produce offsets in process 237(b), a pseudo random number generation process is performed in step 248 for use in generating the offset-Q, which is used to produce a public key. A seed-Q is generated in step 250, which is a numerical value generated from the pseudo random number generator. Using this seed value, a prime number generation process is performed in step 251 with a prime number generator. A prime number is generated in step 252. In step 254, the prime number generated in step 252 is combined with the seed-Q value to produce an offset-Q. This may be done with a simple addition or subtraction logic circuit, a multiplier circuit, or other arithmetic unit. Similar to the offset-P value, the offset-Q is generated in step 255, and stored in step 256, such as in nonvolatile memory, on-chip memory, or other memory storage.

Next, to produce parity values, such as parity bits, process 237(c) is performed, where the ECC parity bits are generated in step 262 using the verified PUF output from step 236. Those skilled in the art will understand that many different methods of parity bit generation exist, and the invention is not limited by any particular method. Examples include BCH code (Bose, Ray-Chaudhuri, Hocquenghem error correction code), and other methods. This value is then stored in step 264, such as in nonvolatile memory, on-chip memory, or other memory storage.

Then, offset-S is generated in process 237(d), for use in producing a signing key, and ultimately a product signature key. In step 258, the verified PUF output is combined with the symmetric encryption key, which is provided by the setup equipment of the device. This produces offset-S, which is then stored in step 260, such as in nonvolatile memory, on-chip memory, or other memory storage.

Thus, the three offset values, offset-P, offset-Q and offset-S are produced in the process 227 and stored in memory. Also, the parity values are produced and stored in memory as well. These offset values and parity values are used by the transfer function circuit to produce security keys, such as a private RSA key, a public RSA key and a product signing key. The encrypted signing key may be produced by a process built into the firmware or other mechanisms in the IC chip. This could be produced during manufacturing, provided post-manufacturing, or by other processes or methods. This is discussed further below in connection with FIGS. 4A and 4B. Those skilled in the art will understand that these functions and features can be provided in various ways.

Referring to FIG. 2C, a more detailed flow chart of the operational mode process 270 is illustrated. The process first includes the corrected PUF output process 271 for correcting the PUF output generated from the PUF using the parity bits stored in memory. In step 272, the process receives a request for authentication, and the novel method is used to produce security keys and related data. According to the invention, this is possible without the burdensome processes used in the prior art, such as algorithms used to produce security keys such as RSA keys and other types of security keys. This occurs during normal operations of a device, wherever and whenever authentication is desired. The process then is followed by parallel process for generating the respective security keys. The secret key process 269(a) produces the secret or private RSA key or Secret key. The public key process 269(b) produces a public key. And, the signing key process 269(c) produces a signing key for producing a product signature. These processes may be performed in a parallel or serial manner, but the separate processes for generating the keys do not necessarily depend on each other for completion. Since, in most RSA applications, two prime numbers are required to produce the private RSA and public RSA key, the parallel processes may be necessary.

Again, the corrected PUF output process 271 begins in step 272 where an authentication request is received. A PUF output is then generated in step 273. In step 274, the error correction process is performed by the ECC, where the PUF output from the PUF and the ECC parity bits from memory are used to generate a corrected PUF output in step 275. This value is used in the three processes 269(a), 269(b) and 269(c) along with the respective offset values, offsets P, Q and S, to produce the respective security keys.

The process 269(a) for generating a secret or private key begins in step 276 where the pseudo random number generation process, PRNG-P is performed. In step 277, the seed value, seed-P, is produced. In step 278, the seed-P is combined with offset-P retrieved from memory. This may be done by simply subtracting the values using addition logic or other processing means, such as subtraction, exclusive or, multiplication or other arithmetic unit. A prime number prime-P is generated in step 279. In step 280, an RSA key generation process is performed, then a secret or private key is generated in step 281.

The process 269(b) for generating a secret or private key begins in step 282 where the pseudo random number generation process, PRNG-Q is performed. In step 283, the seed value, seed-Q, is produced. In step 284, the seed-Q is combined with offset-Q retrieved from memory. This may be done by simply subtracting the values using addition logic or other processing means, such as subtraction, exclusive or, multiplication or other arithmetic unit. A prime number prime-Q is generated in step 285. In step 286, an RSA key generation process is performed, then a public key is generated in step 287.

The process 269(c) for generating a signing key begins in step 288, where the corrected PUF output generated in step 275 is combined with offset-S retrieved from memory. From this, a symmetric decryption key is generated in step 289. In step 290, an encrypted signing key is retrieved from storage, whether on chip memory or from nonvolatile memory. Symmetric encryption is performed in step 291. Examples include Advanced Encryption Standard (AES), such as AES-256, well known to those skilled in the art. The signing key is generated in step 292.

Once the security keys are generated, encrypted data is generated in process 293(a), and a signature key is produced in process 293(b). In both cases, the processes may be performed in parallel or serially, and do not depend on each other for a result. For the encrypted data process 293(a), a public key cryptology process is performed in step 294 using the secret or private key produced in step 281. Examples include the RSA standard, discussed above. Encrypted data is produced in step 295. For the signature key process 293(b), RSA signature generation is performed using the signing key generated in step 292 and the public key generated in step 287. The signature is generated from this process in step 297.

Authentication data is communicated to the authenticating device in step 298. This may be done at the end of the processes discussed above, or throughout the process. In the end, the novel processes performed according to the invention provide a novel means to authenticate a device without the burdensome tasks of performing authentication algorithms each time a device needs to be authenticated. This is because these processes are performed in the setup process discussed above, and offset values are instead used in combination with a PUF output using much more simple processes to generate security keys. As a result, a much improved system and method are provided by the invention for authenticating a device.

Referring to FIG. 3, a diagrammatic view of a sample PUF circuit, used in an integrated circuit identification (ICID) process is illustrated. This particular circuit produces 224 random bits and 32 fixed bits. The circuit includes parallel resistors 302,304, connected at one end to voltage variant circuit 306 via nodes 308,310, and at opposite ends to either ground, a voltage source or other entity. The nodes 308,310 are connected to positive and negative inputs of comparator 312, having output 314. Circuit 306 includes a first transistor 316 connected at one end to node 308, at its gate end to ground 318 and at another end to current source 326. The circuit 306 also includes a second transistor 320 connected on one end to node 310 and at another end to offset voltage source 322, followed by ground 324. This is an example of a circuit that can produce a PUF output for use in a circuit configured according to the invention. Those skilled in the art will understand that there are many different types of circuits that can be used to produce PUF outputs. For example, again referring to U.S. Pat. No. 6,161,213, several examples of particular PUF circuits are illustrated. The invention is not limited to any particular PUF circuit, and indeed extends to any PUF circuit or other entity that can produce a unique security word for use in generating security keys.

Referring to FIGS. 4A and 4 b, more detailed embodiments of the invention are illustrated as incorporated in a generic device, and they will be described first in structure and then in terms of their operation. FIG. 4A is a diagrammatic illustration of a device embodying the invention in an operational mode. That is, this embodiment illustrates a device that has been manufactured and set up. Thus, the processes and operations required to produce the transfer function for this device (specifically the transfer function offsets in this particular embodiment) have been performed and embedded in the device. According to the invention, these processes and operations do not need to be performed any further, and the device can be authenticated without them in a novel manner. FIG. 4B is a diagrammatic illustration of a device embodying the invention in the setup mode, where the processes and operations to produce the transfer function are performed. Once the transfer function is determined at setup, they no longer need to be performed by the device. As discussed above, these embodiments are merely examples of embodiments, and include preferred embodiments. The separate diagrammatic views include selected components or functional blocks to separately describe the operation of a device embodying the invention in operational mode and setup mode respectively. Thus, the device may include some or all components shown separately in the figures. Also, as discussed above, some components, features or functions may exist on or off the device, and some or all of these features or resulting output values may be communicated to the device via a communications channel or other means, or may be include in other devices such as within some setup equipment for example.

Referring first to FIG. 4A, the system 400 includes a device 402 that may communicate with another device 404 or devices via a communication channel 406 for authentication processes or other purposes. For example, the device may be a fingerprint sensor incorporated with an electronic device such as a general purpose personal computer. In such an example, a user may swipe the fingerprint sensor, causing it to generate an authentication signal for the personal computer. The personal computer can then use the signal, which would include security keys, such as secret or private key 408, public key 410 or signature key 412, to authenticate the device. The purpose of this process would be to ensure that the sensor device has been authorized to securely receive fingerprint images from a user to provide access to authorized individuals. Without the security process involving the different keys, a counterfeit device could possibly be used by an unauthorized user to improperly gain access to the personal computer.

In this embodiment, the communication channel includes a plurality of lines, including one for encrypted data or secret key 408, one for the public key 410 and one for the device signature 412, each of which is discussed below. Regardless of the number or configuration of the communication channel, or the different types of security keys utilized by a device, the invention, most generally, is directed to configuring various types of security keys using a PUF circuit together with encryption data stored in the device. Such features and their advantages they provide are discussed in further detail below.

Still referring to FIG. 4A, the device 402 further includes nonvolatile memory 414 configured to store data related to security keys. The nonvolatile memory is configured to store ECC parity bits 416, related to the operations of an error correction circuit, and also to store transfer function parameters 418. These ECC parity bits are then used in generating security keys when combined with a security word from PUF circuit 420. The PUF circuit 420 is configured to generate a PUF output 421, which is a security word that is spontaneously generated from the PUF circuit when it is excited or otherwise enabled.

As discussed above, PUF circuits are well known in the art, and may be configured in many ways. The invention is not limited to any particular PUF circuit, but is directed to taking a PUF output, regardless how it is configured, and using it to generate security keys for a device or system.

Once the PUF output is produced, it is verified in verification circuit 464. In this operation, the output bits produced by the PUF output are verified to ensure consistent, and thus authentic, production of the PUF output in both operational mode and also setup mode discussed below. It has been observed that the PUF output is generally stable, but some bits of the output word may toggle between logic 1 and logic 0, or vice versa, when read out at different times and possibly under different conditions. According to the invention, in order to improve error correction in the subsequent step, verification of the PUF output is performed to produce a dependable output value. The purpose is to prevent or reduce any extra and unnecessary processing and memory burden needed by the error correction processing and circuitry. Thus, it improves error correction by providing a more consistent PUF output value. In one embodiment, this is done by reading the PUF output multiple times, five for example, and choosing the value that is the most consistent or similar to other output values read. An algorithm may be performed, where the multiple PUF values read are evaluated to determine which is the most consistent. For example, several multiple-bit PUF values

The verified PUF output 466 is combined with ECC parity bits in error correction circuit (ECC) 422 to generate a corrected PUF output 426.

The purpose of the ECC is to ensure consistency in the repeated generation of the PUF output upon authentication of the device. Once set up in setup mode, discussed further below, the invention provides a means to consistently generate a PUF output, and in turn generate consistent security keys. Consistency is critical for proper operation of such security operations. For example, a device such as a laptop computer may require authentication upon each powering up the device. Of course, it is critical that the device, when properly configured, be able to power up without being encumbered by security processes. As another example, a fingerprint sensor is enabled by a user upon swiping a finger surface across the sensor. After doing so, a user would be frustrated if the security process ever failed because of a technical error. Thus, consistency in operation is critical for any security device. The invention, by way of the ECC circuit, provides a means for consistently producing security keys for use in authentication.

Furthermore, it is important that any security processes be completed quickly. As discussed in the background, delays in security procedures are intolerable in devices. In either the laptop power up example or the fingerprint sensor example, a user would be frustrated with any unnecessary delays. According to the invention, the time required to complete the process of generating security keys is greatly reduced. This is a result of the unique ability of a device configured according to the invention to obscure security keys by using the PUF circuit. Generation of a security word by the PUF circuit requires no complicated or burdensome processing by a processor, and only requires the generation of security keys with simple processing functions, which are describe below.

In addition to consistency and timeliness, it is imperative that security be maintained in producing such security keys. According to the invention, the corrected PUF output enables the device to generate security keys entirely within the device, securing the process from outside observation or interference. Also, since the PUF output is not stored in memory, it is not vulnerable to interrogation outside the device. Still further, the data stored in memory 414 is but a small part of the key generation process, which cannot be observed or recreated outside the device. The parity bits or transfer function parameters, even if they were observed from outside the device, in no way reveal the output security word of the PUF. Thus, the PUF output can be used to create security words in a manner that cannot be figured out by observers or interrogating entities outside the device.

Still referring to FIG. 4A, the corrected PUF output 426 is transmitted to the transfer function circuit 424, where a secret or private key, a public key and a signature are generated using derivatives of the PUF output. Thus, these keys are derived from a security word generated from the PUF output, making them difficult if not realistically impossible to duplicate for a particular device. A system or device configured according to the invention would be extremely difficult to counterfeit, replicate, interrogate or otherwise breach its security. The corrected PUF output is received by the transfer function circuit in three different paths 428, 430, 432 for use in deriving the three different security keys, the secret or private, the public and the signature keys. The PUF output is illustrated as a 256 bit word, but may be larger or smaller depending on the application. In practice, the corrected PUF output may be used in full or in part by each key producing process. For example, a portion of the corrected PUF or the entire corrected PUF output may be used in each path 428, 430, 432. Alternatively, different portions of the corrected PUF output may be used in different paths to further complicate the process, further obscuring the process required to generate the security keys. Those skilled in the art will understand that different combinations and permutations of the corrected PUF output may be used to derive the different keys, and the invention is not limited to nor obviated by any particular combination chosen for a particular application or embodiment.

In generating a secret or private key, the corrected PUF output is received by a pseudo random number generator 434 to produce a value 438, Seed P. This seed value is received by an arithmetic unit 444, an adder in this particular embodiment, to combine with a corresponding offset value, Offset P. Those skilled in the art will understand that this and other arithmetic units may be implemented as adders, subtraction units, dividers, multipliers, exclusive- or logic units or other arithmetic or logic units implemented to combine the seeds with the offset values. In this particular embodiment, the Seed P is added to Offset P to generate a prime number, Prime P. This is used by a security key generator, such as the RSA key generator 450, to generate the secret or private key for use in authentication. Those skilled in the art will also understand that pseudo random number generators, RSA key generators, and other components discussed herein but not described in explicit detail are well known in the art. Outside the transfer function circuitry, the secret key maybe processed in public key crypto processor. In this operation, encrypted data may be transmitted between another device 404 and the subject device 402, and the secret key may be stored in memory 414 (storage of the secret or private key not illustrated).

Similarly, in generating a public key, the corrected PUF output is received by a pseudo random number generator 436 to produce a value 440, Seed Q. This seed value is received by an arithmetic unit 446, an adder in this particular embodiment, to combine with a corresponding offset value, Offset P. The Seed Q is added to Offset Q to generate a prime number, Prime Q. This is used by a security key generator, such as the RSA key generator 450, to generate the public key, a 2048 bit value in this example, for use in authentication with another device 404.

In this embodiment, the pseudo random number generators 434,436 are preferred to be the same for both operation mode as well as setup mode discussed below. This is to ensure that the RSA operations are consistent when generating the prime numbers, so that the prime numbers used to generate the offset values stored during setup are the same as those used in generating the security keys during operation mode. Those skilled in the art will understand that there are different components that can be duplicated or reused for either the operation mode circuitry and software or setup circuitry and software, and that different applications may require or allow flexibility for different configurations.

The signature key for the device may be generated in a different manner, as illustrated. The purpose of the signature key is to verify the public key by another device, such as device 404. Thus, this is known information and the PUF circuit is used to encrypt the information, adding yet another level of security to the authentication process. In this embodiment, the corrected PUF output 432 is combined with Offset S in arithmetic unit 448 to generate a symmetric decryption key. The symmetric decryption key is combined with an encrypted signing key 452, which may be stored in the device when manufactured, or alternatively in another manner.

The encrypted signing key may be stored in read only memory (ROM) on a chip to save space and cost. Alternatively, it could be stored in non-volatile memory 414. The encrypted signing key 454 may simply be a predetermined digital value, such as the 2048 bit number as illustrated, or may be another derived value. This encrypted signing key is combined in a symmetric decryptor 456. The symmetric decryptor 456 may be composed of any type of arithmetic or logic circuitry, and may be as simple as an adder, a logic exclusive-OR gate, or other such unit. The symmetric decryptor then generates a signing key that is unique to the device, which is combined with the public key in RSA signature generator 458 to produce the signature key for the device, a 2048 bit word in this example, for use in authentication with another device 404.

In operation, the system is configured to perform a method of electronically securing a device by first generating an output from the PUF circuit. In order to authenticate itself, the device is configured to retrieve a transfer function parameter stored in memory and generate a security key. This can be done by performing a transfer function algorithm using the PUF output and a transfer function parameter to produce a public key, private key, and/or a signature. The method may further include performing an error correction process on the PUF output to produce a corrected PUF output; and generating security keys by performing a transfer function algorithm using the corrected PUF output and a transfer function parameter from storage. The process of performing an error correction process may include receiving the PUF output, retrieving ECC parity bits and executing an error correction algorithm using the PUF output and parity bits. Generating security keys includes performing a transfer function algorithm using the PUF output and at least one transfer function parameter from storage.

The PUF correction process, where generating an output from a physically unclonable function (PUF) circuit includes exciting a PUF circuit to produce an initial PUF output, then verifying the PUF output using a verification process to produce a verified PUF output. The invention further provides for performing error correction on the consistent PUF output using error correction parity bits to produce a corrected PUF output. The retrieving of a transfer function parameter from storage includes retrieving a plurality of transfer function offset values stored in non-volatile memory on the device. Thus, generating security keys includes executing a transfer function algorithm using the corrected PUF output and at least one transfer function offset values from storage.

The invention also includes a method for generating prime numbers using a PUF output, in particular a corrected PUF output, to a pseudo random number generator and an offset value, wherein generating security keys includes executing a transfer function algorithm using the corrected PUF output and a transfer function offset value, the method of generating the prime number further includes receiving the PUF output by a pseudo random number generator to produce a seed value and generating a prime number by combining the seed value with a transfer function offset value. The security key is then generated using the prime number. In a preferred embodiment, a plurality of security keys can be generated by receiving the PUF output by a plurality of pseudo random number generators to produce a plurality of seed values. A plurality of prime numbers can then be generated by combining the seed values with corresponding transfer function offset values. The security keys may then be generated using the plurality of prime numbers.

In the embodiment illustrated and discussed above, security keys are generated using two random number generators to generate two prime numbers, where a PUF output, a corrected PUF output in this embodiment, is received by two independent pseudo random number generators to produce two seed values. Two prime numbers are generated by combining the two seed values with corresponding transfer function offset values. Two security keys are then generated using the two prime numbers. The method to ultimately generate security keys includes receiving a PUF output, a corrected PUF output, by a first pseudo random number generator to produce a first seed value, then generating a first prime number by combining the first seed value with a first corresponding transfer function offset value. A secret or private security key is then generated using the first prime number. Then, the a PUF output, a corrected PUF output, is received by a second pseudo random number generator to produce a second seed value. The second prime number is produced by combining the second seed value with a second corresponding transfer function offset value. A public security key is then generated using the second prime number.

A signature key is generated by combining a PUF output with a third offset value. This is done by combining a PUF output with a third offset value to generate an symmetric decryption key, then combining the symmetric decryption key with and encrypted signing key with a symmetric decryptor to produce a signing key. The signing key and the public security key are then combined to generate a signature. In one embodiment, the signature key is generated by retrieving a signature offset value from storage, combining a PUF output with a third offset value to generate a symmetric decryption key, combining the symmetric decryption key with an encrypted signing key with a symmetric decryptor to produce a signing key, and then finally combining the signing key and the public security key to generate a signature.

Referring to FIG. 4B, one configuration of a device components used in setup mode is illustrated. Similar to the description of FIG. 4A, selected components are included to illustrate the operation and structure that are relevant to the device for purposes of explaining the setup mode. Some components necessarily need to be the same as those used in the operation mode in order for the operations to consistently operate during the setup process and also during normal operations, where the device is authenticated during normal use. Those skilled in the art will understand that much variation in component implementation is possible without departing from the spirit and scope of the invention, including location, redundancy, selection, and other aspects of different components, and also that different components may exist on a single integrated circuit chip, different chips or circuit boards, on the device or off. Each of these aspects of the device may vary from application to application depending on the design specifications, variations and restraints.

The system for setup includes the device 402 and setup equipment 462, where communications occur between the device and the setup equipment, including setup commands and parameters. The setup equipment may exist in a manufacture setting Communications may also include authentication communications, where the test equipment acts as another device, such as other device 404 in FIG. 4A, in order to run the device in operation mode. This may be done if it is desired to set up the device in production, and also for testing of the device, whether it is for quality assurance and control or for individual device testing. Those skilled in the art will understand that different marketing professionals, designers or engineers may employ different setup operations for different applications.

The device includes a PUF circuit 420 configured to generate an initial PUF output 421. This is the same as the PUF output 421 used in the operation mode as described above in connection with FIG. 4A. In the setup mode, the PUF output 421 is termed initial PUF output 421 because it needs to be more refined in the setup mode to ensure that the parity bits 416 and transfer function parameters 418 are accurate. This is necessary to ensure proper authentication occurs each time it is required during the operation mode of the device. Thus, a PUF verification module 464 is configured to receive the initial PUF output 421, and produce a verified PUF output 466 in the setup mode. This can be the same operation as the verification operation discussed above with respect to the operational mode. Either way, in a preferred embodiment, the verification operation is performed in both the operational mode and the setup mode in order to better provide a consistent PUF output value. According to the invention, the PUF is unique to each device, and this component needs to be used in both the setup mode and operation mode in a preferred embodiment.

The verified PUF output 466 is transmitted to ECC parity generation circuit 468 and also Setup Function circuit 470. The ECC parity generation 468 circuit may or may not be the same as or incorporated with ECC error correction circuit 422 shown in FIG. 4A. In fact, the ECC parity generation function may be done off the device in setup equipment. One draw back to performing the parity generation off the device is security. If the process is performed on the device, and possibly on the same chip as the PUF or other circuits and components, it is not detectable or observable outside the device. Even if reverse engineered, where the circuit is microscopically dismantled, analyzed or observed, the parity generation would not be easily breached by an intruder. If performed externally, such as by a technician where the device is manufactured and setup, then a security risk exists in that communication link. This may not be a concern in applications where facilities and personnel are relatively secured, and where the communication link has a low risk of being breached. However, in facilities where personnel or facilities are not secured, such a risk may not be acceptable. Those skilled in the art will understand that different applications may call for different configurations when varying risks such as these are at issue.

The setup function circuit 470 is configured to receive a verified PUF output in three separate channels 472, 474 and 476. In the embodiment illustrated, the PUF value is a 256 bit value, which may be larger or smaller depending on a particular application. As discussed above, in practice, the verified PUF output may be used in full or in part by each offset producing process channel. For example, a portion of the verified PUF or the entire verified PUF output may be duplicated for use in each path 428, 430, 432. Alternatively, different portions of the verified PUF output may be used in different paths to further complicate the process, further obscuring the process required to generate the security key offset values. Those skilled in the art will understand that different combinations and permutations of the verified PUF output may be used to derive the different offset values, and the invention is not limited to nor obviated by any particular combination chosen for a particular application or embodiment.

In the first channel, a pseudo random number generator PRNG-P 434 is used to produce a seed-P 438 for use in generating offset value offset-P. The seed value 438 is illustrated as a 1024 bit word, but may be larger or smaller and may depend on the PUF input or the application. This seed-P is transmitted to the prime number generator 480 to produce prime number value prime-P, which is also illustrated here as a 1024 bit word, but may be larger or smaller depending on the application. The prime-P value is then combined with seed-P in arithmetic unit 478 to produce offset value offset-P. The arithmetic unit is shown here as a subtraction unit that typically has subtraction logic. It may, however, be an addition unit, exclusive-or unit, or other logical arithmetic unit. The offset-P value shown here is an 8 bit value, but may be larger or smaller depending on the application. As shown in this embodiment, since this is an offset value, and not a large security key value, the offset value can be relatively small, and thus easily stored in a small amount of memory. According to the invention, this provides a very useful means for storing a small amount of security data for use in generating security keys.

In the second channel, a pseudo random number generator PRNG-Q 438 is used to produce a value seed-Q 440 for use in generating offset value offset-Q. The seed value 440 is illustrated as a 1024 bit word, but may be larger or smaller and may depend on the PUF input or the application. This seed-Q is transmitted to the prime number generator 484 to produce prime number value prime-Q, which is also illustrated here as a 1024 bit word, but may be larger or smaller depending on the application. The prime-Q value is then combined with seed-Q in arithmetic unit 480 to produce offset value offset-Q. The arithmetic unit is shown here as a subtraction unit that typically has subtraction logic. It may, however, be an addition unit, exclusive-or unit, or other logical arithmetic unit. Like the P values, the offset-Q value shown here is an 8 bit value, but may be larger or smaller depending on the application. As shown in this embodiment, since this is an offset value, and not a large security key value, the offset value can be relatively small, and thus easily stored in a small amount of memory. According to the invention, this provides a very useful means for storing a small amount of security data for use in generating security keys.

For the signing key value, verified PUF value 476, also shown here as a 256 bit word, is combined with a symmetric decryption key 457, also shown here as a 256 bit word. The verified PUF output value is then combined with symmetric decryption key 457 in arithmetic unit 482 to produce offset value offset-S. The arithmetic unit is shown here as a subtraction unit that typically has subtraction logic. It may, however, be an addition unit, exclusive-or unit, or other logical arithmetic unit.

In setup mode, the method of generating a signature security key offset includes reading an output from a physically unclonable function (PUF) circuit as a PUF output, computing transfer function parameters using the PUF output; and storing the transfer function parameters in nonvolatile memory for subsequent operations to generate security keys by combining the PUF output with the transfer function parameters. The invention further provides generating error correction parity bits and storing them in memory for subsequent use in generating a corrected PUF output that has been corrected for errors.

Offset values are generated by first generating a first seed value with a first pseudo random number generator. Next, a first prime number is generated with a first prime number generator using the first seed value. Then, a first transfer function offset value is computed using the first seed value and the first prime number. A second seed value is then computed with a second pseudo random number generator. Then, a second prime number is generated using a second prime number generator using the second seed value. A second transfer function offset value is then computed using the second seed value and the second prime number. Computing the first and second offset values may include performing an arithmetic operation using the first seed value and the first prime number. The arithmetic operation may be addition, subtraction division or some other arithmetic operation.

Prior to generating the offset values in the setup mode, the PUF value may be verified by performing a verification algorithm to the PUF output to produce a consistent PUF output. Performing a verification algorithm may include receiving multiple PUF outputs and choosing a statistically consistent output value to produce a consistent PUF output. Alternatively, performing a verification algorithm includes receiving multiple PUF outputs and choosing a statistically consistent output value to produce a consistent PUF output.

The invention may also involve a number of functions to be performed by a computer processor, which may be as simple as combinatorial logic, or may include more complex devices such as a microprocessor. The microprocessor may be a specialized or dedicated microprocessor that is configured to perform particular tasks by executing machine-readable software code that defines the particular tasks. The microprocessor may also be configured to operate and communicate with other devices such as direct memory access modules, memory storage devices, Internet related hardware, and other devices that relate to the transmission of data in accordance with the invention. The software code may be configured using software formats such as Java, C++, XML (Extensible Mark-up Language) and other languages that may be used to define functions that relate to operations of devices required to carry out the functional operations related to the invention. The code may be written in different forms and styles, many of which are known to those skilled in the art. Different code formats, code configurations, styles and forms of software programs and other means of configuring code to define the operations of a microprocessor in accordance with the invention will not depart from the spirit and scope of the invention.

Within the different types of computers, such as computer servers, that utilize the invention, there exist different types of memory devices for storing and retrieving information while performing functions according to the invention. Cache memory devices are often included in such computers for use by the central processing unit as a convenient storage location for information that is frequently stored and retrieved. Similarly, a persistent memory is also frequently used with such computers for maintaining information that is frequently retrieved by a central processing unit, but that is not often altered within the persistent memory, unlike the cache memory. Main memory is also usually included for storing and retrieving larger amounts of information such as data and software applications configured to perform functions according to the invention when executed by the central processing unit. These memory devices may be configured as random access memory (RAM), static random access memory (SRAM), dynamic random access memory (DRAM), flash memory, and other memory storage devices that may be accessed by a central processing unit to store and retrieve information. The invention is not limited to any particular type of memory device, or any commonly used protocol for storing and retrieving information to and from these memory devices respectively.

The apparatus and method include a method and apparatus for providing public and private security keys utilizing a PUF circuit incorporated in an integrated circuit chip and related applications for use in the operation of a electronic device where authentication processes are utilized. In operation, the stored parameters discussed above can be used to more efficiently and quickly authenticate the device without the need to run the burdensome security key generation processes without compromising the level of security in the device. Although this embodiment is described and illustrated in the context of devices, systems and related methods of authenticating devices, the scope of the invention extends to other applications where such functions are useful. Furthermore, while the foregoing description has been with reference to particular embodiments of the invention, it will be appreciated that these are only illustrative of the invention and that changes may be made to those embodiments without departing from the principles of the invention. 

1. A method of electronically securing a device, comprising: generating an output from a physically unclonable function (PUF) circuit to produce a PUF output; retrieving a transfer function parameter; and generating a security key by performing a transfer function algorithm using the PUF output and a transfer function parameter.
 2. A method according to claim 1, further comprising: performing an error correction process on the PUF output to produce a corrected PUF output; and generating security keys by performing a transfer function algorithm using the corrected PUF output and a transfer function parameter from storage.
 3. A method according to claim 2, wherein performing an error correction process includes receiving the PUF output, retrieving ECC parity bits and executing an error correction algorithm using the PUF output and parity bits.
 4. A method according to claim 3, further comprising performing a verification process on the PUF output before error correction.
 5. A method according to claim 3, further comprising performing a verification process on the PUF output after error correction.
 6. A method according to claim 1, wherein generating security keys includes performing a transfer function algorithm using the PUF output and at least one transfer function parameter from storage.
 7. A method according to claim 1, wherein generating an output from a physically unclonable function (PUF) circuit includes exciting a PUF circuit to produce a PUF output, performing a verification algorithm to produce a consistent PUF output, and performing error correction on the consistent PUF output using error correction parity bits to produce a corrected PUF output; wherein retrieving a transfer function parameter from storage includes retrieving a plurality of transfer function offset values stored in memory; and wherein generating security keys includes executing a transfer function algorithm using the corrected PUF output and at least one transfer function offset value from storage.
 8. A method according to claim 1, wherein generating security keys includes executing a transfer function algorithm using the corrected PUF output and a transfer function offset value, the method further including: receiving the PUF output by a pseudo random number generator to produce a seed value; generating a prime number by combining the seed value with a transfer function offset value; and generating a security key using the prime number.
 9. A method according to claim 1, further comprising generating a plurality of security keys by: receiving the PUF output by a plurality of pseudo random number generators to produce a plurality of seed values; generating a plurality of prime numbers by combining the seed values with corresponding transfer function offset values; and generating security keys using the plurality of prime numbers.
 10. A method according to claim 1, further comprising generating a plurality of security keys by: receiving the PUF output by two independent pseudo random number generators to produce two seed values; generating two prime numbers by combining the two seed values with corresponding transfer function offset values; and generating a security key using the plurality of prime numbers.
 11. A method according to claim 1, further comprising generating a plurality of security keys by: receiving a PUF output by a first pseudo random number generator to produce a first seed value; generating a first and second prime number by combining the first seed value with first and second corresponding transfer function offset values; receiving a PUF output by a second pseudo random number generator to produce a second seed value; generating a second prime number by combining the second seed value with a second corresponding transfer function offset value; and generating a private and a public security key using the first and second prime numbers.
 12. A method according to claim 11, further comprising: combining a PUF output with a third offset value to generate a decryption key for use in decrypting encrypted data.
 13. A method according to claim 11, further comprising: combining a PUF output with a third offset value to generate an symmetric decryption key; combining the symmetric decryption key with and encrypted signing key with a symmetric decrypt or to produce a signing key; and combining the signing key and the public security key to generate a signature.
 14. A method according to claim 11, further comprising: retrieving a signature offset value from storage; combining a PUF output with a third offset value to generate a symmetric decryption key; combining the symmetric decryption key with an encrypted signing key with a symmetric decrypt or to produce a signing key; and combining the signing key and the public security key to generate a signature.
 15. A method for electronically securing a device, comprising: generating an output from a physically unclonable function (PUF) circuit to produce a PUF output; retrieving a signature transfer function parameter; combining the PUF output with the signature transfer function parameter to generate a symmetric decryption key; combining the symmetric decryption key with an encrypted signing key using a symmetric decryptor to produce a signing key; and combining the signing key and a public security key to generate a signature security key.
 16. A method for electronically securing a device, comprising: reading an output from a physically unclonable function (PUF) circuit as a PUF output; computing transfer function parameters using the PUF output; and storing the transfer function parameters in nonvolatile memory for subsequent operations to generate security keys by combining the PUF output with the transfer function parameters.
 17. A method according to claim 16, further comprising generating error correction parity bits and storing them in memory for subsequent use in generating a corrected PUF output that has been corrected for errors.
 18. A method according to claim 16, wherein computing the transfer function parameters includes generating a plurality of offset values by: generating a first seed value with a first pseudo random number generator; generating a first prime number with a first prime number generator using the first seed value; computing a first transfer function offset value with the first seed value and the first prime number; generating a second seed value with a second pseudo random number generator; generating a second prime number with a second prime number generator using the second seed value; and computing a second transfer function offset value with the second seed value and the second prime number.
 19. A method according to claim 18, wherein computing a plurality of offset values include performing an arithmetic operation using the first seed value and the first prime number.
 20. A method according to claim 18, wherein computing a plurality of offset values include adding the first seed value with the first prime number.
 21. A method according to claim 18, wherein computing a plurality of offset values include subtracting the first seed value from the first prime number.
 22. A method according to claim 18, wherein computing a plurality of offset values include dividing the first seed value by the first prime number.
 23. A method according to claim 16, further comprising: performing a verification algorithm to the PUF output to produce a consistent PUF output.
 24. A method according to claim 23, wherein performing a verification algorithm includes receiving multiple PUF outputs and choosing a statistically consistent output value to produce a consistent PUF output.
 25. A method according to claim 23, wherein performing a verification algorithm includes receiving multiple PUF outputs and choosing a statistically consistent output value to produce a verified PUF output according to predetermined parameters.
 26. A method according to claim 16, further comprising generating an output security parameter by calculating key pairs as the security parameter.
 27. A method according to claim 16, wherein the PUF output and the security parameter are integers, and the security output is larger than the PUF output; wherein defining the transfer function includes identifying an arithmetic expression of a transfer function.
 28. A method according to claim 27, wherein the arithmetic expression is of the form y=mx+b, wherein the value of m and b are stored in data storage, and wherein x is the value of the PUF output, and y is the resultant security parameter.
 29. A method according to claim 27, wherein the next time when a security parameter is needed, reading the PUF and applying the transfer function.
 30. A system for electronically securing a device, comprising: a physically unclonable circuit configured to generate a persistent random number a security word; nonvolatile memory configured to store at least one transfer function parameter; and a processor configured to generate a security key by processing the security word and the transfer function.
 31. A system according to claim 30, wherein the physically unclonable circuit is made up of a plurality of integrated circuit components configured to generate a binary value when excited to define the security word.
 32. A system according to claim 30, wherein the physically unclonable circuit is made up of a series of ring oscillators configured to generate a binary value when excited that defines the security word. 